A Guide to Servers: Their Usage, History, and Evolution

Servers have become an essential part of modern technology. They are used for a wide range of purposes, including data storage, communication, and cloud computing. In this blog, we will explore the history of servers, their evolution, and their importance in the digital age.

History of Servers:

Servers have been around since the early days of computing. In the 1960s, mainframe computers were used as servers to store and process data. These early servers were large and expensive, and only large corporations and government agencies could afford to use them.

As technology evolved, servers became smaller and more affordable. In the 1980s, personal computers became popular, and companies began using them as servers for local networks. In the 1990s, the internet became widely available, and servers were used to host websites and provide email services.

Evolution of Servers:

As technology continued to evolve, servers became more powerful and versatile. Today, servers are used for a wide range of purposes, including data storage, communication, cloud computing, and virtualization.

Cloud computing has become particularly popular in recent years. With cloud computing, servers are used to store and process data in remote locations, allowing users to access their data from anywhere in the world. This has led to a shift away from traditional on-premises servers to cloud-based servers.

Usage of Servers:

Servers are used for a wide range of purposes, including:

1.    Data Storage: Servers are used to store data, including documents, images, and videos. They provide a centralized location for data storage, making it easy for users to access their data from anywhere.

2.    Communication: Servers are used to provide email, chat, and other communication services. They allow users to communicate with each other in real-time, no matter where they are located.

3.    Cloud Computing: Servers are used to provide cloud computing services, including infrastructure as a service (IaaS), platform as a service (PaaS), and software as a service (SaaS). These services allow users to access computing resources on demand, without having to invest in their own hardware.

4.    Virtualization: Servers are used to provide virtualization services, allowing multiple virtual machines to run on a single physical server. This can help organizations save money on hardware costs and reduce their environmental footprint.

Servers have come a long way since their early days as mainframe computers. Today, they are an essential part of modern technology, used for a wide range of purposes. With cloud computing and virtualization, servers are more powerful and versatile than ever before. As technology continues to evolve, servers will undoubtedly play an increasingly important role in the digital age.

Servers can be broadly categorized into different types based on their function, hardware specifications, and intended usage. Here are some of the most common types of servers and a brief explanation of each:

1.    Web servers: These servers are designed to host websites and web applications. They typically run specialized software like Apache or Nginx that can handle HTTP requests and serve static and dynamic content to web clients.

2.    Database servers: These servers are optimized for storing, managing, and retrieving data from databases. They typically run database management systems (DBMS) like MySQL, Oracle, or Microsoft SQL Server.

3.    Application servers: These servers provide a runtime environment for running applications. They can run on a variety of platforms and languages like Java, .NET, or Python.

4.    Mail servers: These servers are used to handle email traffic, storing and forwarding messages between mail clients and other mail servers. They typically run specialized software like Postfix or Sendmail.

5.    File servers: These servers are used to store and manage files and provide access to them over a network. They may use a variety of protocols like SMB, NFS, or FTP to allow clients to access shared files.

6.    Print servers: These servers are used to manage printing services on a network. They typically run specialized software that can handle multiple print requests from different clients and manage print queues.

7.    DNS servers: These servers are used to resolve domain names into IP addresses. They typically run a DNS server software like BIND or Windows DNS Server.

8.    Proxy servers: These servers act as intermediaries between clients and other servers on a network. They can be used for caching content, filtering requests, or enhancing security.

There are many other types of servers as well, but these are some of the most common. Each type of server has its own hardware and software requirements, as well as specific configuration and management considerations.

Servers typically use processors that are designed for high performance and high reliability, as they are expected to handle heavy workloads and operate continuously. Here are some of the most common types of processors used in servers:

1. x86 processors: These processors are based on the Intel x86 architecture and are widely used in servers. They are known for their versatility, power efficiency, and high performance.
2. ARM processors: These processors are based on the ARM architecture and are increasingly being used in servers, particularly for energy-efficient workloads. They are commonly used in low-power servers, IoT devices, and edge computing applications.
3. Power processors: These processors are designed by IBM and are used in IBM Power Systems servers. They are known for their high performance and scalability, as well as their support for virtualization and workload consolidation.
4. SPARC processors: These processors are designed by Oracle and are used in Sun SPARC-based servers. They are known for their high reliability, availability, and serviceability, as well as their support for mission-critical applications.
5. MIPS processors: These processors are used in a variety of server and networking applications, particularly in embedded systems and routers. They are known for their power efficiency and low cost.

Each type of processor has its advantages and disadvantages, and the choice of a processor depends on the specific requirements of the server workload. Factors like performance, power efficiency, scalability, and compatibility with software applications all need to be considered when selecting a processor for a server.

The processors used in servers can vary depending on the specific model and configuration. However, here is a general overview of the types of processors used by the server manufacturers mentioned earlier:

1. Dell Technologies: Dell's servers use processors from Intel and AMD, including Xeon and EPYC processors.
2. Hewlett-Packard Enterprise (HPE): HPE's servers also use processors from Intel and AMD, including Xeon and EPYC processors.
3. Lenovo: Lenovo's servers use processors from Intel and AMD, including Xeon and EPYC processors.
4. IBM: IBM's servers use processors from IBM's own POWER family, as well as processors from Intel and AMD.
5. Cisco: Cisco's servers use processors from Intel, including Xeon processors.
6. Fujitsu: Fujitsu's servers use processors from Intel and AMD, including Xeon and EPYC processors.
7. Oracle: Oracle's servers use processors from Oracle's own SPARC family, as well as processors from Intel and AMD.
8. Supermicro: Supermicro's servers use processors from Intel and AMD, including Xeon and EPYC processors.
9. Huawei: Huawei's servers use processors from Huawei's own Kunpeng and Ascend families, as well as processors from Intel and AMD.

In terms of operating systems, the servers listed here can typically run a wide range of operating systems. Common operating systems include:

• Windows Server
• Linux (including Red Hat, CentOS, and Ubuntu)
• Unix (including AIX, HP-UX, and Solaris)
• VMware ESXi
• Citrix Hypervisor
• FreeBSD

However, the specific operating systems supported by a server will depend on its hardware and firmware, as well as the drivers and software available for that particular platform.

Here is a list of some proprietary operating systems and the servers that run these operating systems:

1. IBM i: IBM i is a proprietary operating system from IBM that runs on IBM Power Systems servers. IBM i is designed for mid-sized and large organizations and provides a high level of reliability, security, and scalability. IBM i includes many built-in applications and services, including a database management system, web server, and application server.
2. z/OS: z/OS is a proprietary operating system from IBM that runs on IBM z Systems mainframe servers. z/OS is designed for large-scale enterprise environments and provides high performance, reliability, and security. z/OS includes many built-in applications and services, including a database management system, web server, and application server.
3. Oracle Solaris: Oracle Solaris is a proprietary operating system from Oracle that runs on Oracle servers. Solaris is designed for businesses of all sizes and provides advanced features such as built-in virtualization, advanced file systems, and integrated security. Solaris includes many built-in applications and services, including a database management system, web server, and application server.
4. HPE NonStop: HPE NonStop is a proprietary operating system from Hewlett Packard Enterprise that runs on HPE NonStop servers. NonStop is designed for organizations that require high availability, high performance, and high scalability. NonStop includes many built-in applications and services, including a database management system, web server, and application server.
5. Unisys OS 2200: Unisys OS 2200 is a proprietary operating system from Unisys that runs on Unisys ClearPath servers. OS 2200 is designed for businesses of all sizes and provides high reliability, security, and scalability. OS 2200 includes many built-in applications and services, including a database management system, web server, and application server.

Here's a list of some popular proprietary operating systems and the servers that run them:

1.    Microsoft Windows Server: This operating system is developed by Microsoft and is designed for server use. It is used by many organizations for various purposes, including web servers, database servers, and application servers.

2.    IBM AIX: AIX is a proprietary operating system developed by IBM for use on their servers. It is commonly used in enterprise environments and is known for its reliability and scalability.

3.    Oracle Solaris: Solaris is a Unix-based proprietary operating system developed by Oracle. It is commonly used for mission-critical applications and database servers.

4.    HP-UX: HP-UX is a proprietary Unix-based operating system developed by Hewlett Packard (now HP Enterprise). It is commonly used in enterprise environments and is known for its scalability and reliability.

5.    Red Hat Enterprise Linux: Red Hat Enterprise Linux (RHEL) is a proprietary Linux-based operating system developed by Red Hat. It is commonly used for server use and is known for its stability and security.

6.    SUSE Linux Enterprise Server: SUSE Linux Enterprise Server (SLES) is a proprietary Linux-based operating system developed by SUSE. It is commonly used for server use and is known for its stability and security.

7.    IBM z/OS: This is a proprietary operating system developed by IBM for their mainframe computers.

8.    IBM i: This is another proprietary operating system developed by IBM for their midrange computers.

9.    VMS: VMS (Virtual Memory System) is a proprietary operating system developed by Digital Equipment Corporation (DEC) for their VAX and Alpha server systems.

10. OpenVMS: OpenVMS is a successor to VMS, also developed by DEC, which was later acquired by HP.

11. OS/400: This is a proprietary operating system developed by IBM for their AS/400 and iSeries computers.

12. Solaris: Solaris is a proprietary operating system developed by Sun Microsystems, which was later acquired by Oracle Corporation. It is used on their SPARC-based servers.

13. AIX: AIX (Advanced Interactive eXecutive) is a proprietary operating system developed by IBM for their Power Systems servers.

14. HP-UX: HP-UX (Hewlett Packard-Unix) is a proprietary operating system developed by Hewlett-Packard (now Hewlett Packard Enterprise) for their HP 9000 and Integrity server systems.

These are just a few examples, and there are many other proprietary operating systems and servers available on the market.

Some examples of servers that run these operating systems are:

• IBM zSeries mainframes for z/OS and iSeries servers for OS/400 and IBM i.
• DEC VAX and Alpha server systems for VMS and OpenVMS.
• SPARC-based servers for Solaris.
• IBM Power Systems servers for AIX.
• HP 9000 and Integrity servers for HP-UX.

Here is a list of servers that run some of the operating systems I mentioned in my previous answer:

1. IBM zSeries mainframes: These servers run IBM's proprietary operating systems, including z/OS and IBM i.
2. IBM iSeries servers: These servers run IBM's proprietary operating system, OS/400, which has been renamed to IBM i.
3. DEC VAX and Alpha server systems: These servers run Digital Equipment Corporation's proprietary operating systems, VMS and OpenVMS.
4. Sun SPARC-based servers: These servers run Solaris, a proprietary operating system developed by Sun Microsystems, which was later acquired by Oracle Corporation.
5. IBM Power Systems servers: These servers run AIX, a proprietary operating system developed by IBM.
6. Hewlett-Packard (now Hewlett Packard Enterprise) servers: These servers run HP-UX, a proprietary operating system developed by Hewlett-Packard for their HP 9000 and Integrity server systems.

Here is a list of some of the top IT server manufacturing companies and a brief overview of their product lines:

1. Dell Technologies - Dell Technologies offers a wide range of server solutions including PowerEdge rack servers, modular servers, tower servers, and blade servers.
2. Hewlett-Packard Enterprise (HPE) - HPE offers a variety of server solutions including ProLiant rack and tower servers, Apollo high-performance computing servers, and Moonshot microservers.
3. Lenovo - Lenovo offers a range of server solutions including ThinkSystem rack servers, tower servers, blade servers, and high-density servers.
4. IBM - IBM offers a range of server solutions including Power Systems servers, z Systems mainframes, and LinuxONE servers.
5. Cisco - Cisco offers a range of server solutions including UCS C-Series rack servers, UCS B-Series blade servers, and UCS Mini servers.
6. Fujitsu - Fujitsu offers a range of server solutions including PRIMERGY rack servers, PRIMEQUEST mission-critical servers, and SPARC servers.
7. Oracle - Oracle offers a range of server solutions including SPARC servers, x86 servers, and Engineered Systems.
8. Supermicro - Supermicro offers a range of server solutions including SuperServer rack servers, SuperBlade blade servers, and MicroBlade microservers.
9. Huawei - Huawei offers a range of server solutions including KunLun high-end servers, FusionServer rack servers, and Atlas AI computing platforms.

This is not an exhaustive list, and many other companies manufacture servers. The products offered by these companies may vary based on the specific needs of the customer.

Here is a brief description of the server products offered by each of the companies mentioned:

1. Dell Technologies: Dell's PowerEdge servers are a popular choice for businesses of all sizes. They offer a range of server options including rack servers, modular servers, tower servers, and blade servers. These servers are designed to provide high performance, reliability, and scalability to handle the demands of modern business applications.
2. Hewlett-Packard Enterprise (HPE): HPE's ProLiant servers are designed for small and mid-sized businesses, as well as enterprise-level organizations. They offer a range of server options including rack and tower servers, blade servers, and high-performance computing servers. These servers are designed to deliver high performance, scalability, and energy efficiency.
3. Lenovo: Lenovo's ThinkSystem servers are designed for data center environments and offer a range of server options including rack servers, tower servers, blade servers, and high-density servers. These servers are designed to provide high performance, scalability, and energy efficiency, while also offering advanced security and management features.
4. IBM: IBM's server offerings include Power Systems servers, z Systems mainframes, and LinuxONE servers. Power Systems servers are designed for businesses of all sizes and are ideal for running mission-critical workloads. z Systems mainframes are designed for large-scale enterprise environments and offer unparalleled security and reliability. LinuxONE servers are designed for organizations looking to run Linux-based workloads at scale.
5. Cisco: Cisco's UCS servers are designed for data center environments and offer a range of server options including rack servers, blade servers, and mini servers. These servers are designed to deliver high performance, scalability, and efficiency, while also offering advanced networking and management features.
6. Fujitsu: Fujitsu's PRIMERGY servers are designed for small and mid-sized businesses, as well as enterprise-level organizations. They offer a range of server options including rack servers, tower servers, and mission-critical servers. These servers are designed to deliver high performance, scalability, and energy efficiency.
7. Oracle: Oracle's server offerings include SPARC servers, x86 servers, and Engineered Systems. SPARC servers are designed for running mission-critical applications and offer high performance and reliability. x86 servers are designed for businesses of all sizes and offer a range of performance and scalability options. Engineered Systems are pre-configured hardware and software solutions designed to run specific workloads such as databases or analytics.
8. Supermicro: Supermicro's server offerings include SuperServer rack servers, SuperBlade blade servers, and MicroBlade microservers. These servers are designed for a range of use cases including data center environments, cloud computing, and high-performance computing.
9. Huawei: Huawei's server offerings include KunLun high-end servers, FusionServer rack servers, and Atlas AI computing platforms. These servers are designed for businesses of all sizes and offer a range of performance and scalability options, as well as advanced features such as AI acceleration and high-density computing.

All of the servers mentioned are still in production today, although some of them may have newer and more advanced models available.

For example, IBM zSeries mainframes have continued to evolve with new models and capabilities, and IBM iSeries servers have been rebranded as IBM Power Systems running IBM i.

DEC VAX and Alpha servers are no longer being produced, but OpenVMS continues to be supported and is used by some organizations for mission-critical applications.

Sun SPARC-based servers are still in production, with Oracle continuing to develop and support Solaris as well as their SPARC hardware platform.

IBM Power Systems servers are also still in production, with newer models available that offer improved performance and capabilities.

Hewlett Packard Enterprise continues to support HP-UX, although they have shifted their focus towards their newer Linux-based operating system, called HPE OpenVMS.

Fujitsu is a Japanese multinational information technology equipment and services company that offers a wide range of server products for various applications. Here are some of the server models offered by Fujitsu, along with the operating systems that are typically run on them:

1. PRIMERGY servers: Fujitsu's PRIMERGY servers are designed for small, medium, and large enterprises, and can run a variety of operating systems, including Windows Server, VMware, and Linux (such as Red Hat Enterprise Linux and SUSE Linux Enterprise Server).
2. PRIMEQUEST servers: Fujitsu's PRIMEQUEST servers are designed for mission-critical applications and can run Windows Server, VMware, and Linux (such as Red Hat Enterprise Linux and SUSE Linux Enterprise Server), as well as Fujitsu's proprietary operating system, Solaris.
3. SPARC M12 servers: Fujitsu's SPARC M12 servers are based on the Oracle SPARC architecture and can run Oracle Solaris operating system.
4. BS2000 servers: Fujitsu's BS2000 servers are designed for mainframe-class applications and can run Fujitsu's proprietary operating system, BS2000/OSD.
5. ETERNUS storage systems: Fujitsu's ETERNUS storage systems can support a wide range of operating systems, including Windows, Linux, and Unix.

Note that Fujitsu offers many other server and storage products, and the specific operating system that can run on them may vary depending on the model and configuration.

BS2000/OSD is a proprietary operating system developed by Fujitsu for its mainframe-class BS2000 servers. The acronym "OSD" stands for "Operating System Division" and represents the division within Fujitsu that is responsible for developing and maintaining the operating system.

BS2000/OSD is designed for high reliability, availability, and scalability, and can support large-scale, mission-critical applications. It includes features such as virtualization, workload management, and fault tolerance to ensure that applications can run continuously and reliably even in the face of hardware failures.

The operating system is designed to support multiple programming languages, including COBOL, PL/I, Assembler, and C/C++, as well as various database systems such as Oracle, IBM DB2, and SAP HANA. It also includes built-in security features such as access control, authentication, and encryption to protect sensitive data and ensure compliance with regulatory requirements.

BS2000/OSD can be customized and configured to meet the specific requirements of a given application or workload and can run multiple instances of the operating system on a single physical server. This allows for efficient use of resources and can help to reduce costs and complexity in large-scale computing environments.

Servers typically use processors that are designed for high performance and high reliability, as they are expected to handle heavy workloads and operate continuously. Here are some of the most common types of processors used in servers:

1. x86 processors: These processors are based on the Intel x86 architecture and are widely used in servers. They are known for their versatility, power efficiency, and high performance.
2. ARM processors: These processors are based on the ARM architecture and are increasingly being used in servers, particularly for energy-efficient workloads. They are commonly used in low-power servers, IoT devices, and edge computing applications.
3. Power processors: These processors are designed by IBM and are used in IBM Power Systems servers. They are known for their high performance and scalability, as well as their support for virtualization and workload consolidation.
4. SPARC processors: These processors are designed by Oracle and are used in Sun SPARC-based servers. They are known for their high reliability, availability, and serviceability, as well as their support for mission-critical applications.
5. MIPS processors: These processors are used in a variety of server and networking applications, particularly in embedded systems and routers. They are known for their power efficiency and low cost.

Each type of processor has its advantages and disadvantages, and the choice of a processor depends on the specific requirements of the server workload. Factors like performance, power efficiency, scalability, and compatibility with software applications all need to be considered when selecting a processor for a server.

SISC (Single Instruction Set Computer) and RISC (Reduced Instruction Set Computer) are two different types of processor architectures.

SISC processors are designed to handle a wide range of instructions and operations, making them more flexible but also more complex. They can execute instructions that perform a variety of tasks, which allows them to run a wide range of software applications. However, the complexity of SISC processors can make them slower and less efficient when executing certain types of instructions, which can limit their performance for specific workloads.

RISC processors, on the other hand, are designed to execute a smaller set of simple and efficient instructions. This allows them to perform specific operations quickly and efficiently, which can make them well-suited for certain types of workloads like database processing, scientific computing, and image processing. RISC processors also tend to have a simpler and more streamlined design, which can make them easier to manufacture and less expensive to produce.

Overall, the choice of processor architecture depends on the specific requirements of the server workload. Workloads that require a wide range of operations may benefit from SISC processors, while workloads that require fast and efficient execution of specific instructions may benefit from RISC processors.

Here is a list of processors in both SISC and RISC categories:

SISC processors:

1. Intel x86 processors (e.g., Intel Core i7, Intel Xeon)
2. AMD processors (e.g., AMD Ryzen, AMD EPYC)
3. IBM System z processors (e.g., z14, z15)
4. Fujitsu SPARC64 processors (e.g., SPARC64 IXfx, SPARC64 XIfx)

RISC processors:

1. ARM processors (e.g., ARM Cortex-A, ARM Cortex-M)
2. IBM POWER processors (e.g., POWER9, POWER10)
3. Oracle SPARC processors (e.g., SPARC T8, SPARC M8)
4. MIPS processors (e.g., MIPS32, MIPS64)

Note that some processors can fall into both categories, depending on how they are designed and optimized. For example, Intel Xeon processors are primarily SISC processors but have some RISC-like features and optimizations for specific workloads. Similarly, some ARM processors can support a wider range of instructions and may have more SISC-like characteristics, while others are optimized for specific tasks and have more RISC-like features.